DE1076767B - Termination for a waveguide - Google Patents

Description

The invention relates to a closure for a waveguide carrying high frequency power of a given frequency with a short circuit across the waveguide and a part of resistance material that extends across the waveguide in the front of the Short circuit, the part of resistance material from a thin electrical Resistance film consists in the form of a single covering, which is located on an insulating plate, and which has an electrical conductivity that is much greater than that of the insulating material, the plate is arranged such that the resistive film is approximately a quarter wavelength apart the predetermined frequency of the short circuit and preferably in its plane within the Waveguide is movable.

Such degrees are known per se.

The waveguide according to the invention of this type is characterized in that the covering is narrow Forms strip that has a width that is small compared to the cross-sectional dimensions of the hot conductor.

By making the plate movable in its own plane, the effective impedance that the Filmstrip offers the impinging field, can be adjusted.

When applying the invention to a termination for a rectangular waveguide is the electrical Vector expediently parallel to the narrow inner surfaces of the waveguide and the resistance strips then extends transversely to the waveguide between its wider inner surfaces.

Such a design offers considerable advantages over the previously known types of adapted Terminations for rectangular waveguides in which a resistive film covers the entire cross-sectional area of the Waveguide covered, there one. much lower resistance per unit area of film is used can be. It is also possible to use a film covering of known resistance per unit area, regardless of what total resistance of the strip is required; because the width of the The strip can be set up to provide the necessary effective impedance. In this way standardization of the manufacturing process is facilitated. With such a degree for one rectangular waveguide, the impedance presented to the field, a maximum when the Strip is located in the middle of the waveguide, and the resistance between the two ends of the strip should be made larger than the wave impedance. Moving the strip across to one side of the Waveguide, the effective impedance can thereby be reduced and so the wave impedance of the Waveguide to be adapted.

Applicant:

The Decca Record Company Limited,
London

Representative: Dipl.-Ing. F. Weickmann

and Dr.-Ing. A. Weickmann, patent attorneys,

Munich 2, Brannstr. 8/9

Claimed priority:
Great Britain January 29, 1958 and January 22, 1959

Deryck Arthur John Walliker, London,
has been named as the inventor

To terminate a circular waveguide, said plate can be a circular plate and the strips extend transversely diametrically to the plate. The plate can in the waveguide around its axis be rotatably arranged to change the effective impedance of the termination.

Preferably the film is formed from vapor deposited metal. It has been found that a nickel-chromium film is particularly suitable; Such a nickel-chromium film can easily be deposited on glass, ceramic or silica in a reproducible manner and then forms a stable film which has a low temperature coefficient of resistance in temperature ranges which usually occur and which is an extremely high degree of Has stability to atmospheric changes, for example to changes in humidity. Such an evaporated metal film is preferably applied to a glass plate, and a thin glass plate can be used. For a frequency in the order of 10,000 megahertz such a glass plate may be in the order of ² / _iOO o to V ₁₀₀₀ cm thick to the effects of the glass, which has a higher dielectric constant than air, and therefore affect the operation of the statements, to diminish. Such an arrangement has been found to be very

909 758/362

compact shape of a waveguide termination, which has a relatively wide bandwidth and which is based on Grtmd the adjustability of the position of the film within the waveguide can be easily adjusted to make an adjustment to a required impedance.

The film is preferably on the surface side the plate that the incoming waves hit. This can reduce the capacitive impedance that due to the discontinuity on the other plate surface, can be compensated if one of the Plate is stored appropriately with respect to the short circuit. To reduce this impedance, it is preferred the plate is made as thin as possible, or alternatively it is the whole area between the resistance strip and the short circuit filled with the plate material. In the latter Case, the resistance strip can be carried by a thin plate to make it movable, which abuts against the thick plate which fills the space between the thin plate and the short circuit. The use of such a thick plate has the advantage that due to the high dielectric constant of the plate material compared to air, the length of the termination is reduced because the distance of the short circuit from the film is less than in an air-filled waveguide. Furthermore is such an arrangement of particularly solid construction and allows with greater accuracy Set the filmstrip with respect to the short circuit.

The use of a resistive film strip on a relatively thick glass backing is not necessary limited to a construction in which the strip is movable across the width of the waveguide. The short circuit can have an axially movable plunger, and the insulating plate, which carries the resistance film, can in this case be attached to the plunger. Interchangeable Plates, the resistance layers of which are arranged in different transverse layers, can be provided to set the effective impedance of the termination.

Some exemplary embodiments of the invention are described, reference being made to the drawing is.

Fig. 1 shows a perspective view, partly in section, of a termination for a rectangular horn;

Fig. 2 shows a longitudinal section of a waveguide termination, which is a modification of the embodiment of Figure 1;

3 shows a perspective view, partly in section, of a termination for circular waveguides;

Fig. 4 shows in a perspective view, partially in section, another termination for a rectangular Waveguide.

Fig. 1 shows a rectangular waveguide ΙΟ, _{is fed into the power in an E 01} mode, in the direction of arrow A. The electrical vector of this propagation mode is, as known, perpendicular to the wider surface of the waveguide, so parallel to the directed towards narrower surfaces. The waveguide is terminated by a fixed short circuit which is formed by a conductive plate 11 which extends across one end of the waveguide over its entire cross section. In front of this plate, at a distance that effectively corresponds to a quarter of a wavelength at the operating frequency, a plate 12 made of insulating material, preferably made of glass, is arranged, which is displaceable in the direction of arrows B , i.e. parallel to the wider ones Surfaces of the waveguide. For this purpose, slots are provided in the narrower surfaces of the waveguide. On the front side of the plate 12, on the side of the incident power, a narrow resistance strip 13 is produced, namely as a thin film on the plate by the precipitation of evaporated nickel-chromium. The width of the strip is small compared to the cross-sectional dimensions of the waveguide 10. Such a thin film can easily be deposited on glass in a reproducible manner by evaporating the nickel-chromium in a vacuum and gives a stable film with a very low temperature coefficient of the electrical Has resistance, namely in a temperature range as it is usually used and which is also extremely stable against atmospheric changes, z. B. against changes in humidity. Since a very narrow strip of the resistive film is used, this film can have a low resistance per unit area. This facilitates the deposition of a film of known electrical properties. The strip is made sufficiently narrow to give the required effective impedance. By making the plate 12 movable in its own plane, one can adjust the effective impedance presented by the filmstrip to the incident wave, if necessary, to match the wave impedance of the waveguide. The resistance of the strip is preferably made only slightly higher than the wave impedance of the conductor, so that the necessary adaptation can be obtained by only small movements of the strip from the center of the waveguide. Since the resistive film is applied to the face of the plate 12, the capacitive impedance created by the discontinuity on the other face of the plate can easily be compensated for by properly adjusting the plate with respect to the short circuit. This impedance is minimized by making the plate 12 as thin as possible in an arrangement according to FIG. 1 so that the distance between the insulating plate 12 and the short circuit 11 is essentially a quarter of a conductor wavelength in air. In a typical case, for a frequency on the order of 10,000 megahertz, the plate 12 will be only ² 1/2 to 1,000 cm thick.

Fig. 2 shows a modification of the construction of Fig. 1. The same reference numerals denote in essentially identical parts. In the arrangement according to FIG. 2, however, the entire space is within the waveguide between the plate 12 and the short circuit 11 with a thick plate of insulating material 14 filled. The material of this plate is preferably similar to the material used to manufacture it the plate 12 is used. In order to facilitate the adjustment of the position of the strip 13, this is a film strip deposited on a thin plate 12 as described above, and the plate is transversely movable. In this way, the position of the strip can be changed without the need for the thick plate 14 to move. The use of such a thick plate 14 has the advantage that on Due to the high dielectric constant compared to air, the overall length of the termination is reduced is compared to an arrangement according to FIG. 1. Incidentally, such an arrangement is from FIG

more stable construction and allows greater accuracy the adjustment of the strip 13 with respect to the short circuit.

Fig. 3 shows an adapted termination for a circular HofaWeiter 20, which at one end through a short circuit 21 in the form of a conductive plate which extends across the waveguide over its entire Cross-section extends, is closed. A quarter wavelength in the front of the short circuit 21 there is a thin glass plate 22. on which a narrow strip 23 of a deposited nickel-chromium film is located across a surface the plate extends. This plate can be rotatably arranged in the waveguide, or it can also be the entire termination unit including the waveguide 20 about the axis of the waveguide with respect to the polarization the incident power can be made rotatable. Such rotation of the strip 23 in relation to the electrical vector changes the effective impedance, and therefore the device simulates FIG. 3 shows an adjustable conformal termination in a manner similar to the arrangement of FIG. In Fig. 3, a construction with a thin glass plate 22 is shown, in which the strip 23 is on the side of the plate facing the incident signals. The entire space between the strip 23 and the short circuit 21 can be filled with insulating material. In this Trap, the strip 23 may be deposited on a cylindrical block, the length of which is one Quarter wavelength in the waveguide corresponds. This block can then be rotated in the waveguide.

In some cases it may not be necessary to adjust the position of the filmstrip transversely to be provided opposite the waveguide. In this case, as shown in Fig. 4, a thin resistor film can be used in the form of a narrow strip 30, for example a vapor-deposited nickel-chromium film, be formed on one surface of a thick glass plate 31 filling a length of the waveguide and which carries a conductive plate 32 on its rear surface, which forms a short circuit across the waveguide forms. The strip 30 extends in the direction of the electrical vector and has a width which is small compared to the cross-sectional dimensions of the waveguide. The glass plate 31 is made thick so that the distance between the short circuit and the strip 30 is effectively one Quarter wavelength. In the arrangement of FIG. 4, the block 31 is in its axial position in Waveguide made adjustable. For this purpose, an adjustable rod 33 for moving the block 31 is longitudinal the waveguide axis provided. It is readily understood that by choosing a suitable Resistance for the strip 30 obtained a very compact adapted termination for a waveguide when the construction according to FIG. 4 is applied. In the arrangement according to FIG. 4, exchangeable blocks 31 can, if necessary, be provided, on which the resistance strip 30 is in different transverse positions, in order to, if so what is required is the effective impedance of the termination to adjust.

Claims (14)

Claims ·. 65 1. Degree for a waveguide, the high frequency power of a given frequency leads, with a short circuit across the waveguide and a part made of resistance material, which extends transversely to the waveguide in the front of the short circuit, the part made of resistance material consists of a thin electrical resistance film in the form of a single covering, which is located on an insulating plate and which has an electrical conductivity that is much greater than that of the insulating material, where ^ - in which the plate is arranged such that the resistive film is approximately a quarter wavelength apart at the predetermined frequency of the short circuit and preferably movable in its plane within the waveguide is, characterized in that the covering forms a narrow strip which has a width that is small compared to the cross-sectional dimensions of the waveguide. 2. Termination for a waveguide according to claim 1, characterized in that the plate made of glass. 3. Termination for a waveguide according to claim 1, characterized in that the plate made of ceramic. 4. termination for a waveguide according to claim 1, characterized in that the plate consists of silica, 5. Termination for a waveguide according to one of the preceding claims for the conclusion of a rectangular waveguide, characterized in that the electrical vector of the high-frequency oscillations is directed in the waveguide parallel to the narrow inner surfaces of the waveguide that the resistance strip extends transversely to the waveguide between its broad inner surfaces and that the insulating plate transversely to the waveguide in a direction parallel to the wide inner surfaces of the waveguide is movable. 6. Termination for a waveguide according to one of the preceding claims, characterized in that that the plate of insulating material has a thickness which is small compared to the distance between the resistance strip and the short circuit. 7. termination for a waveguide according to claim 6, characterized in that the resistance strip is applied to the surface side of the insulating plate on which the incident Wave hits. 8. termination for a waveguide according to claim 6 or 7, characterized in that one thick sheet of insulating material, the space between the thin, the resistance layer supporting insulating plate and the short circuit fills. 9. Termination for a waveguide according to one of claims 1 to 4, to terminate a waveguide with a circular cross-section, characterized in that the insulating plate is circular and the strip extends diametrically across the plate. 10. Termination for a waveguide according to claim 9, characterized in that the insulating plate is rotatable about its axis in the waveguide. 11. Termination for a waveguide according to one of claims 1 to 8, characterized in that that it is adapted to a rectangular waveguide. 12. Termination for a waveguide according to claim 11, characterized in that the short circuit an axially movable plunger and that the insulating plate carrying the resistance strip is attached to this plunger is attached. 13. Termination for a waveguide according to one of the preceding claims, characterized in that that the resistance strip is formed from vapor-deposited metal. 14. Termination for a waveguide according to claim 13, characterized in that the resistor Stand strip is formed from vapor-deposited nickel-chromium. Considered publications: U.S. Patent No. 2,151,118; British Patent No. 732,683; S out worth, G. C, “Principles and Applications of Waveguide Transmission ", New York, 1950/1954, p. 377. 1 sheet of drawings